Interface Function Design and Bone-Regenerative Engineering of Biomimetic Biomaterials by Supersonic Treatment Using Electrolyzed Water

Toshiyuki Akazawa; Masaru Murata; Y. Minamida; Md. Arafat Kabir; M. Ito; Akihiko Katayama; T. Nakajima

doi:10.4028/www.scientific.net/KEM.631.241

Paper Titles

Development and Characterization of Hydroxyapatite Containing Silver by Precipitation and Immersion Methods
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Chemical and Heat Treatments for Inducing Bone-Bonding Ability of Ti-6Al-4V Pedicle Screw
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Fabrication of Bioactive Apatite Nuclei Precipitated Ti-15Mo-5Zr-3Al Alloy by Using Doubled Sandblasting Process
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Novel Bone-Like Porous Glass Coatings on Al₂O₃ Prosthetic Substrates
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Interface Function Design and Bone-Regenerative Engineering of Biomimetic Biomaterials by Supersonic Treatment Using Electrolyzed Water
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Formation of Calcium-Phosphate Coatings on Ti6Al4V Substrates by an Autocatalytic Deposition Route
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Effect of Poling Treatment on Piezoelectric Constant of Pulsed Laser Deposited Hydroxyapatite Thin Films
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Evaluation of Dentin Tubule Sealing Rate Improved by Attaching Ultrathin Amorphous Calcium Phosphate Sheet
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A Novel Treatment for Dentine Cavities with Intraoral Laser Ablation Method Using an Er:YAG Laser
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 631Interface Function Design and Bone-Regenerative...

Interface Function Design and Bone-Regenerative Engineering of Biomimetic Biomaterials by Supersonic Treatment Using Electrolyzed Water

Abstract:

As interface design of autotransportation materials and bioactive ceramics by supersonic treatment, human teeth-originated granules and commercial hydroxyapatite (HAp) were partially dissolved in different acid solutions, such as electrolyzed water and HNO₃ aqueous solution to control bio-absorption, adsorption-release of bone growth factor and anti-bacterial characteristics. Human teeth were pulverized with cooling, dissolved in strongly acidic electrolyzed water (pH 2.6-3.1) or 2.0% HNO₃ solution to obtain demineralized dentin matrix granules. For supersonic or stirring demineralization in the acidic electrolyzed water, dissolution efficiencies (DE) were 3-12% and dentinal tubules with 1-2μm were found, while for supersonic demineralization in the HNO₃ solution, DE was attained to the highest value of 86%. When HAp was dissolved with stirring in the acidic electrolyzed water, DE of porous ceramics was lower than that of spherical particles due to smaller specific surface area and good crystallinity. For supersonic dissolution of porous ceramics in the acidic electrolyzed water, DE was 30% and extension of grain boundary and micro-crack were observed. Concerning supersonic irradiation of the electolyzed water to parietal bone in rats by using ultrasonic scaler, enlargement and propagation of micro-crack were recognized on the hard tissues.

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Key Engineering Materials (Volume 631)

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241-246

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https://doi.org/10.4028/www.scientific.net/KEM.631.241

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Online since:

November 2014

Authors:

Toshiyuki Akazawa*, Masaru Murata, Y. Minamida, Md. Arafat Kabir, M. Ito, Akihiko Katayama, T. Nakajima

Keywords:

Biomimetic Materials, Bone-Regeneration, Electrolyzed Water, Interface Function, Microstructure, Supersonic Treatment, Ultrasonic Scaler

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